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path: root/src/py/cam/cam_qt.py
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# SPDX-License-Identifier: GPL-2.0-or-later
# Copyright (C) 2022, Tomi Valkeinen <tomi.valkeinen@ideasonboard.com>
#
# Debayering code from PiCamera documentation

from io import BytesIO
from numpy.lib.stride_tricks import as_strided
from PIL import Image
from PIL.ImageQt import ImageQt
from PyQt5 import QtCore, QtGui, QtWidgets
import numpy as np
import sys


def rgb_to_pix(rgb):
    img = Image.frombuffer('RGB', (rgb.shape[1], rgb.shape[0]), rgb)
    qim = ImageQt(img).copy()
    pix = QtGui.QPixmap.fromImage(qim)
    return pix


def demosaic(data, r0, g0, g1, b0):
    # Separate the components from the Bayer data to RGB planes

    rgb = np.zeros(data.shape + (3,), dtype=data.dtype)
    rgb[r0[1]::2, r0[0]::2, 0] = data[r0[1]::2, r0[0]::2]  # Red
    rgb[g0[1]::2, g0[0]::2, 1] = data[g0[1]::2, g0[0]::2]  # Green
    rgb[g1[1]::2, g1[0]::2, 1] = data[g1[1]::2, g1[0]::2]  # Green
    rgb[b0[1]::2, b0[0]::2, 2] = data[b0[1]::2, b0[0]::2]  # Blue

    # Below we present a fairly naive de-mosaic method that simply
    # calculates the weighted average of a pixel based on the pixels
    # surrounding it. The weighting is provided by a byte representation of
    # the Bayer filter which we construct first:

    bayer = np.zeros(rgb.shape, dtype=np.uint8)
    bayer[r0[1]::2, r0[0]::2, 0] = 1  # Red
    bayer[g0[1]::2, g0[0]::2, 1] = 1  # Green
    bayer[g1[1]::2, g1[0]::2, 1] = 1  # Green
    bayer[b0[1]::2, b0[0]::2, 2] = 1  # Blue

    # Allocate an array to hold our output with the same shape as the input
    # data. After this we define the size of window that will be used to
    # calculate each weighted average (3x3). Then we pad out the rgb and
    # bayer arrays, adding blank pixels at their edges to compensate for the
    # size of the window when calculating averages for edge pixels.

    output = np.empty(rgb.shape, dtype=rgb.dtype)
    window = (3, 3)
    borders = (window[0] - 1, window[1] - 1)
    border = (borders[0] // 2, borders[1] // 2)

    rgb = np.pad(rgb, [
        (border[0], border[0]),
        (border[1], border[1]),
        (0, 0),
    ], 'constant')
    bayer = np.pad(bayer, [
        (border[0], border[0]),
        (border[1], border[1]),
        (0, 0),
    ], 'constant')

    # For each plane in the RGB data, we use a nifty numpy trick
    # (as_strided) to construct a view over the plane of 3x3 matrices. We do
    # the same for the bayer array, then use Einstein summation on each
    # (np.sum is simpler, but copies the data so it's slower), and divide
    # the results to get our weighted average:

    for plane in range(3):
        p = rgb[..., plane]
        b = bayer[..., plane]
        pview = as_strided(p, shape=(
            p.shape[0] - borders[0],
            p.shape[1] - borders[1]) + window, strides=p.strides * 2)
        bview = as_strided(b, shape=(
            b.shape[0] - borders[0],
            b.shape[1] - borders[1]) + window, strides=b.strides * 2)
        psum = np.einsum('ijkl->ij', pview)
        bsum = np.einsum('ijkl->ij', bview)
        output[..., plane] = psum // bsum

    return output


def to_rgb(fmt, size, data):
    w = size[0]
    h = size[1]

    if fmt == 'YUYV':
        # YUV422
        yuyv = data.reshape((h, w // 2 * 4))

        # YUV444
        yuv = np.empty((h, w, 3), dtype=np.uint8)
        yuv[:, :, 0] = yuyv[:, 0::2]                    # Y
        yuv[:, :, 1] = yuyv[:, 1::4].repeat(2, axis=1)  # U
        yuv[:, :, 2] = yuyv[:, 3::4].repeat(2, axis=1)  # V

        m = np.array([
            [1.0, 1.0, 1.0],
            [-0.000007154783816076815, -0.3441331386566162, 1.7720025777816772],
            [1.4019975662231445, -0.7141380310058594, 0.00001542569043522235]
        ])

        rgb = np.dot(yuv, m)
        rgb[:, :, 0] -= 179.45477266423404
        rgb[:, :, 1] += 135.45870971679688
        rgb[:, :, 2] -= 226.8183044444304
        rgb = rgb.astype(np.uint8)

    elif fmt == 'RGB888':
        rgb = data.reshape((h, w, 3))
        rgb[:, :, [0, 1, 2]] = rgb[:, :, [2, 1, 0]]

    elif fmt == 'BGR888':
        rgb = data.reshape((h, w, 3))

    elif fmt in ['ARGB8888', 'XRGB8888']:
        rgb = data.reshape((h, w, 4))
        rgb = np.flip(rgb, axis=2)
        # drop alpha component
        rgb = np.delete(rgb, np.s_[0::4], axis=2)

    elif fmt.startswith('S'):
        bayer_pattern = fmt[1:5]
        bitspp = int(fmt[5:])

        # \todo shifting leaves the lowest bits 0
        if bitspp == 8:
            data = data.reshape((h, w))
            data = data.astype(np.uint16) << 8
        elif bitspp in [10, 12]:
            data = data.view(np.uint16)
            data = data.reshape((h, w))
            data = data << (16 - bitspp)
        else:
            raise Exception('Bad bitspp:' + str(bitspp))

        idx = bayer_pattern.find('R')
        assert(idx != -1)
        r0 = (idx % 2, idx // 2)

        idx = bayer_pattern.find('G')
        assert(idx != -1)
        g0 = (idx % 2, idx // 2)

        idx = bayer_pattern.find('G', idx + 1)
        assert(idx != -1)
        g1 = (idx % 2, idx // 2)

        idx = bayer_pattern.find('B')
        assert(idx != -1)
        b0 = (idx % 2, idx // 2)

        rgb = demosaic(data, r0, g0, g1, b0)
        rgb = (rgb >> 8).astype(np.uint8)

    else:
        rgb = None

    return rgb


# A naive format conversion to 24-bit RGB
def mfb_to_rgb(mfb, cfg):
    data = np.array(mfb.planes[0], dtype=np.uint8)
    rgb = to_rgb(cfg.pixel_format, cfg.size, data)
    return rgb


class QtRenderer:
    def __init__(self, state):
        self.state = state

        self.cm = state['cm']
        self.contexts = state['contexts']

    def setup(self):
        self.app = QtWidgets.QApplication([])

        windows = []

        for ctx in self.contexts:
            camera = ctx['camera']

            for stream in ctx['streams']:
                fmt = stream.configuration.pixel_format
                size = stream.configuration.size

                window = MainWindow(ctx, stream)
                window.setAttribute(QtCore.Qt.WA_ShowWithoutActivating)
                window.show()
                windows.append(window)

        self.windows = windows

    def run(self):
        camnotif = QtCore.QSocketNotifier(self.cm.efd, QtCore.QSocketNotifier.Read)
        camnotif.activated.connect(lambda x: self.readcam())

        keynotif = QtCore.QSocketNotifier(sys.stdin.fileno(), QtCore.QSocketNotifier.Read)
        keynotif.activated.connect(lambda x: self.readkey())

        print('Capturing...')

        self.app.exec()

        print('Exiting...')

    def readcam(self):
        running = self.state['event_handler'](self.state)

        if not running:
            self.app.quit()

    def readkey(self):
        sys.stdin.readline()
        self.app.quit()

    def request_handler(self, ctx, req):
        buffers = req.buffers

        for stream, fb in buffers.items():
            wnd = next(wnd for wnd in self.windows if wnd.stream == stream)

            wnd.handle_request(stream, fb)

        self.state['request_prcessed'](ctx, req)

    def cleanup(self):
        for w in self.windows:
            w.close()


class MainWindow(QtWidgets.QWidget):
    def __init__(self, ctx, stream):
        super().__init__()

        self.ctx = ctx
        self.stream = stream

        self.label = QtWidgets.QLabel()

        windowLayout = QtWidgets.QHBoxLayout()
        self.setLayout(windowLayout)

        windowLayout.addWidget(self.label)

        controlsLayout = QtWidgets.QVBoxLayout()
        windowLayout.addLayout(controlsLayout)

        windowLayout.addStretch()

        group = QtWidgets.QGroupBox('Info')
        groupLayout = QtWidgets.QVBoxLayout()
        group.setLayout(groupLayout)
        controlsLayout.addWidget(group)

        lab = QtWidgets.QLabel(ctx['id'])
        groupLayout.addWidget(lab)

        self.frameLabel = QtWidgets.QLabel()
        groupLayout.addWidget(self.frameLabel)

        group = QtWidgets.QGroupBox('Properties')
        groupLayout = QtWidgets.QVBoxLayout()
        group.setLayout(groupLayout)
        controlsLayout.addWidget(group)

        camera = ctx['camera']

        for k, v in camera.properties.items():
            lab = QtWidgets.QLabel()
            lab.setText(k + ' = ' + str(v))
            groupLayout.addWidget(lab)

        group = QtWidgets.QGroupBox('Controls')
        groupLayout = QtWidgets.QVBoxLayout()
        group.setLayout(groupLayout)
        controlsLayout.addWidget(group)

        for k, (min, max, default) in camera.controls.items():
            lab = QtWidgets.QLabel()
            lab.setText('{} = {}/{}/{}'.format(k, min, max, default))
            groupLayout.addWidget(lab)

        controlsLayout.addStretch()

    def buf_to_qpixmap(self, stream, fb):
        with fb.mmap() as mfb:
            cfg = stream.configuration
            w, h = cfg.size
            pitch = cfg.stride

            if cfg.pixel_format == 'MJPEG':
                img = Image.open(BytesIO(mfb.planes[0]))
                qim = ImageQt(img).copy()
                pix = QtGui.QPixmap.fromImage(qim)
            else:
                rgb = mfb_to_rgb(mfb, cfg)
                if rgb is None:
                    raise Exception('Format not supported: ' + cfg.pixel_format)

                pix = rgb_to_pix(rgb)

        return pix

    def handle_request(self, stream, fb):
        ctx = self.ctx

        pix = self.buf_to_qpixmap(stream, fb)
        self.label.setPixmap(pix)

        self.frameLabel.setText('Queued: {}\nDone: {}\nFps: {:.2f}'
                                .format(ctx['reqs-queued'], ctx['reqs-completed'], ctx['fps']))